Weighing and checkweighing machine



Dec. 6, 1955 w. J. SCHIESER ETAL WEIGHING AND CHECKWEIGHING MACHINE Filed Oct. 21, 1952 s Sheets-Sheet 1 Fl?! E Flll INVENTORS. warren J. Schieser John F. Kelley BY Richard M. White Lawrence W. Hoffman ATTORNEYS.

Dec. 6', 1955 w. J. SCHIESER ETAL 2,726,061i

WEIGHING AND CHECKWEIGHING MACHINE Filed OCt. 21, 1952 8 Sheets-Sheet 2 INVENTORS. warren J. Schieser John F. Kelley BY Richard M White Lawrence W. Hoffman W, W ,4 M

V ATTORNEYS.

Dec. 6, 1955 w. J. SCHIESER ETAL 2,726,061

WEIGHING AND CHECKWEIGHING MACHINE Filed Oct. 21, 1952 8 Sheets-Sheet 4 2 W o 60 y: H]

k J 8/ r Q [I 80 $64 INVENTORS. Warren J. Schieser FI I l 5 John Fv Kelley BY Richard M. White A TTORNEYS.

6, 1955 w. J. SCHIESER ETAL 2,726,061

WEIGHING AND CHECKWEIGHING MACHINE Filed Oct. 21, 1952 8 Sheets-Sheet 5 INVENTORS. Warren J. Schieser John F. Kelley Richard Mv White Lawrence W. Hoffman M, w M

A TTORNEYS.

Dec. 6, 1955 Filed Oct. 21, 1952- W. J- SCHIESER ETAL WEIGHING AND CHECKWEIGHING MACHINE 8 Sheets-Sheet '7 Fuji EU INVENTORS. Warren J. Schieser John F. Kelley Richard M. White Lawrence W. Hoffman ATTORNEYS.

Dec. 6, 1955 w. J. SCHIESER ErAL WEIGHING AND CHECKWEIGHING MACHINE 8 Sheets-Sheet 8 Filed Oct. 21, 1952 mm m 0S ef Tfm HM N wfi m m V ue w K e W mEmm ,r A mmmw w wmm W W United States Patent WEIGHING AND CHECKWEIGHIN G MACHINE Warren J. Schieser, John F. Kelley, Richard M. White, and Lawrence W. Hoffman, Columbus, Ohio, assigners to The Exact Weight Scale Company, Columbus, Ghio, a corporation of Ohio Application October 21, 1952, Serial No. 315,906

' .54 Claims. (Cl. 249-4 Our invention relates to a weighing and checkweighing machine. It hasto do, more specifically; with a weighing and checkweighing machine of the over-and-under weight or even balance type, although various features of our invention are not limited to a machine of that type.

Our scale is especially designed for accurately weighing and checkweighing powder charges which are subsequently loaded into explosive shells, but it is capable of use in weighing and checkweighing other commodities or materials where extreme accuracy is required. The powder for explosive shells is usually in the form of small pellets which are supplied to the shell-loading plant in bulk or loose condition; Our weighing machine is designed to receive these pellets in bulk and feed a predetermined amount of the pellets onto a weighing unit form-v ing a part or" our machine, to obtain a charge of predeterminedweight; and then to feed the weighed charge on to a checkweighing unit forming a part of our machine, where the charge is checkweighed and is classified as correctweight, overweight or underweight, and if out of tolerance, is rejected and dumped into a suitable receiver, or if within tolerance is dumped into a receiver for the accurately weighed and checkweighed charge.

One of the objects of our. invention. is to provide a weighing and checkweighing scale of the general type indicated above which is extremely sensitive and, therefore, extremely accurate.

Another object of our invention is to provide a scale which is not only extremely sensitive and extremely accurate, but whichis so designed that the weighing and checkweighing units will be protected from severe shocks ordinarily resulting in prior art machines from the dumping of the weighed and checkweighed charges from such units.

Still another object of our invention is to provide a weighing and checkweighing scale of the general type indicated above, which canbe set. for completely automatic operation, for semiautomatic operation, or for manual operation by pushoutton, depending upon what type of operation is desired which will, in turn, depend upon circumstances ofuse of the machine.

7 Various other objects will. beapparent from the following description and the drawings.

The preferred embodiment of our invention is illustrated in the accompanying drawings wherein similar characters of, reference designate corresponding parts, and wherein:

Figure l is a side elevational view of a weighing and checkweighing machine constructed invention.

Figure 2 is a front elevational view of the machine.

Figure I is anenlarged sideelevational view showing the weighing unit of the machine, including the weighing bucket-and associated dumping mechanism.

Figure 4 is a transverse vertical sectional view taken substantially along line 4-4.01":v Figure-3t Figure 5 is a vertical sectional view taken along line 5-5 of Figure 3 illustrating one of the pin and slot mountings for supporting the weighing bucket on the according to our- ICC weighing lever in association with the dumping mechanism.

Figure 6 is a plan view,with some parts removed, of the Weighing bucket and associated dumping mechanism shown in Figure 3.

Figure 7 is an enlarged transverse vertical sectional view taken substantially along line 77 of Figure 6.

Figure 8 is an enlarged transverse vertical sectional view taken substantially along line 8-8 of Figure 6.

Figure 9 is a detail of the connection between the bucket-tilting rod and the bucket.

Figure 10 is a schematic view in side elevation illustrating the weighingbucket and the checkweighing bucket with their respectively associated dumping mechanisms, and indicating how the checkweighing bucket receives the charge fromthe weighing bucket.

Figure 11 is an enlarged perspective view of the lower end of the feeding chutes which feedthe pellets into the weighing and checkweighing buckets.

Figure 12 is a side elevational view illustrating the vibrating units for the main feed chutes.

Figure 13 is a transverse vertical sectional view taken substantially along line 1313 of Figure 11.

Figure 14 is a detail in plan of the counterweight end of the weighing lever and associated means for controlling the vibrating units of the manual feeding unit of our machine.

Figure 15 is a side elevational view of the structure of Figure 14.

Figure 16 is a transverse vertical sectional view taken along line 16-16 of Figure 15.

Figure 17 is a view like Figure 16 but showing part of the means associated with the checkweighing lever for controlling the weight-classification system of our machine.

Figure l8 is a schematic'diagram of the air system of our machineusedfor controlling lifting and dumping of the weighing and checkweighing buckets of our machine.

1 Figure 19 is an enlarged schematic view illustrating an associated pilot valve, four-way valve and ram unit controlled thereby, which are part of the system of Figure 18.

Figure 20 is a schematic diagram of a portion of the electric circuit used in controlling the various operations of ourmachine.

Figure 20a is a schematic diagram of the remaining portion ofthe electric circuit.

With reference to the drawings, in Figures 1 and 2, we have illustrated the general 'ararngement of our weighingand checkweighing machine. it comprises several main units which are: the feeding unit 21; the weighing unit 22; and the check-weighing unit 23. The feeding unit 21 is supported at a relatively high level by a frame 24. The units 22 and 23-are supported by an independent frame 25, so that vibration of the feeding unit frame 24 will have no effect on the frame 25 and the weighing units carried thereby. it will be apparent from Figures 1 and 2, that the frames. 24 and 25 are of such relative height that the weighing unit 22, which is carried at the upper end of frame 25, is at a slightly lower level than the feed ingunit-21. Also, it will be noted that frame 25 is dis posed laterally to'the right-of unit 21 (Figure 2). Thus, weighing unit 22 is slightly lower than andslightly to the right of the feeding unit 21. The checkweighing unit 23, it will be noted; isdisposed on the frame 25 at a slightly lower level than and directly below the weighing unit 22. Withthis arrangement, the pellets-to be weighed into a charge will be received in bulk by the feeding unit 21 and checked for accurate weight. and will be classified exact weight, underweight or overweight, the charge if it is exact weigt, being then dumped into one receiver and the charge if it is overweight or underweight, being dumped into another receiver. The feeding unit 21 and the weighing and checkweighing units 22 and 23 are controlled by suitable controls, to be described hereinafter, so that the feeding, weighing, and checkweighing operations can be completely automatic, semi-automatic, or manual by pushbutton.

The feeding unit 21 comprises an upright hopper 26 which is of funnel shape and is carried by the upstanding extension 27 of the frame 24. The lower end of this hopper 26 extends into the rearward end of the main feed chute 28. Cables 29 are used for movably suspending the hopper 26 between the uprights of the frame extension 27 so that the lower end of the hopper can be swung forwardly or rearwardly relative to the chute 28. A yoke 39 extends transversely of the uprights of the frame extension 27 and is carried thereby, this yoke having an adjustable connecting rod 31 connected thereto, the opposite end of the rod (not shown) being pivotally connected to the rear side of the hopper 26. With this arrangement, the lower end of the hopper 26 may be swung forwardly or rearwardly relative to the chute 28 and will be held in adjusted position.

The main chute 28 of the feeding unit 21 is vibrated by a vibrating unit 35 (Figure 12). This unit 35 may be of the electromagnetic type and, when energized, imparts rapidly occurring vibrations to the chute 28, which may be inclined forwardly and downwardly, as shown, or may be level. The amplitude of vibration may be adjusted so as to provide a controlled positive feed of the pellets through the chute 28.

The vibrating unit 35 and chute 28 are carried on suitable supports 36 and 37, which are carried by the frame 24, the unit being mounted on cushioning springs 38, which dampen the vibrations imparted to the frame 24.

Directly alongside the main feed chute 28, at the lefthand side thereof (Figure 2) is the auxiliary feed or dribble feed chute 40. The relative arrangement of these chutes is also illustrated in Figures 11 and 13. The chute 40 may be level or inclined and is vibrated by an independent vibrating unit 39 like the unit 35. This unit is supported on a horizontal platform 41 which, in turn, is supported by the vertical posts 42 (Figures 1 and 12) on the frame 24. Cushioning springs 43 are provided for absorbing vibration created by the unit 39. The chute 40 extends parallel to and beyond the front portion of the chute 28. It will be noted from Figure 11 that the adjacent wall 44 of the main chute 28 is provided with an opening 45 for the pellets to feed into the chute 40 during vibration of the chute 28. The chute 28 is fiat and wide (Figure 13) but chute 40 is of an L shape crosssection with its outer wall 46 inclined upwardly and outwardly, and with its inner wall 47 disposed at a declined angle, and sloped downwardly and outwardly from the lower portion of the chute 28, so that pellets P feeding through the opening 45 of the main chute 28 will roll outwardly towards outer wall 46 of the chute 40. To ensure that the chute 40 will feed only a single line of the pellets P, which are of cylindrical form as shown in Figure 11, in end-to-end relationship in a horizontal plane, an opening 48 is provided in the inner wall 47 of the chute 40 to permit excess pellets P to drop from the chute 40, if there is more than a single line of pellets P being fed up to the opening 48 in the chute 40. The chute 40 is narrowed further into V-formation (Figure 11) at its extreme forward end to positively form the single line of pellets. Any pellets P which drop through the opening 48 will fall onto an apron 49 (Figure 13) which extends from beneath the chute 28, which carries it, laterally beneath the chute 40. As previously indicated, the forward end of the chute 28 is behind the forward end of the chute 40. It will be noted from Figure 11 that the forward end of the apron 49 terminates flush with the forward end of the chute 28 and the open- 4 ing 48 is located rearwardly of the forward end of the chute 40 so that the pellets P, dropping through the opening 48, will drop onto the apron 49. The adjacent portions of the chute 40 are spaced sufiiciently from the chute 28 (Figure 13) so that the two chutes can vibrate independently without interference.

The chutes 28 and 40, as shown in Figures 1, 2, and 11, discharge into separate sections of a directing hopper 50 which is carried by the weighing unit 22. This hopper is rigidly supported by the upstanding brackets 51 (Figures 10 and ll) carried by the weighing unit bucket 52. It will be noted that the directing hopper 50, carried by the weighing bucket 52, is located directly below the chutes 28 and 40. The main section 53 of the hopper 50 is provided with an inclined bottom 54 with which the pellets P will contact when dropping from the chute 28 and apron 49, this arrangement serving to break the fall of the pellets so that the shock therefrom will have less effect on the weighing unit 22 during the weighing operation. The other section 55 of the hopper 50 extends laterally in a horizontal plane so as to receive and retain the pellets P dropping from the chute 40, and at the time of dumping, of the bucket 52, discharge them into the directing chute 52a which is carried by an extension 25a of the frame 25 as shown in Figure 2.

The weighing unit 22 is illustrated best in Figures 1 to 10 inclusive. It is illustrated as being of the evenbalance type. It comprises a weighing lever 60, consisting of parallel arms rigidly connected together, which is fulcrumed midway its ends by the knife-edge pivot 61 which rests in the V-bearings 62. The V-bearings 62 are carried on the upright center yoke 63, mounted on the base 25b which in turn is supported on frame 25. The weighing end of the lever carries the commodity outrider 64 which is suspended from the lever 60 by means of the upright arms 65 (Figure 4). The upper ends of these arms 65 carry the inverted V-bearings 66 which rest on the knife-edge pivots 67 which are carried by the commodity end of the lever 60. The opposite end of the weighing lever 60 carries the counterweight outrider 68 through the medium of the inverted V-bearings 69, on the outrider, which rest on the knife-edges 70 carried by the Weighing lever 60. The commodity and counterweight outriders 64 and 68 are connected together at their lower ends by a checkrod which is pivoted thereto and part of which is illustrated at 71 in Figure 3.

The weighing lever 60 may be connected to any suitable type of over-and-under indicating mechanism for indicating the position of the lever in the weighing operation. However, we prefer to use that type of indicator known as the Shadograph and illustrated in the U. S. patent to Sullivan, No. 2,335,200, issued November 23, 1943, whereby the deflection of the lever is indicated by projecting the image of an index member by a mirror or mirrors to a position in the window 72 at the upper end of the indicating tower 73 which is supported at the righthand upper corner of the frame 25, with the window 72 facing towards the left (Figure 3). However, other indicator arrangements may be provided. The indicating mechanism is controlled by means of an arm 60a which is rigidly attached to the adjacent end of the lever 60 and extends into the tower 73 (Figure 3).

The commodity outrider 64 is adapted to carry the weighing bucket 52 during the weighing operation. This weighing bucket 52 (Figure 4) is disposed between the upright arms 65 of the commodity outrider 64. Rigidly attached to the bottom (Figure 3) of this weighing bucket 52 at the lefthand side thereof is a pair of relative short posts 75 and rigidly attached to the center of the righthand inwardly extending wall thereof is a single longer post 76 (Figure 3). All of these posts have cups formed in their lower ends to mate with upright adjustable pointed pins projecting vertically from the outrider 64, the posts 75 mating with the pins 77 and I post 76gmating with the-pin 78, it being notedjthat pins 77 are much shorter than the pin 78; During the weighing operation, the posts 75 and" 76 rest on the respective pins 77 and 78. These pins can be relatively adjusted to level the weigh scale bucket 52.

After the weighing operation, the, weighing bucket 52 is dumped outwardly, as shown by the dotted lines in Figure 3. During this dumping operation it is desirable to have the bucket 52 supported independently of the lever 60 so that the shocks created during the dumping operation will not be transmitted to the lever 68 and its associated sensitive knife-edges and V-bearings. Also, it is desirable to have the lever 60 free of the weight of the dumping mechanism. Therefore, we provide the arrangement shown in the drawings whereby the weighing bucket 52 is first lifted from the lever. 60 and is then dumped.

This lifting mechanism comprises a pair of normally upright semi-circular plates 80 (Figure. 3) which are locatedat opposite sides of the weighing bucket 52 (Figure 4) and are spaced therefrom. These plates 80 are pivotally carried on the lefthand end of a bucketsupporting frame 81 (Figure 6), the plates being pivoted to the frame by pivots 82 which are located at the lower curved edges of the plates 80 (Figure 3) midway between the righthand and lefthand edges thereof. The bucket-supporting frame 81 is pivoted for. vertical swinging movement by means of a transverse sleeve 83 (Figures 6 and 8) which is integrally formed with the frame 81 and is supported by a pivot rod 84. The ends of this rod 84 are supported in the upper ends of upright supporting arms 85 on a yoke carried by the weighing unit base b. The arms 85 are ofsuch height that the sleeve 83 will be located above the lever 60 at such a level that it will not interfere with the rise and fall of the lever. The frame 81 can be swung vertically by means of a link 86 (Figure 8) which has its upper end pivoted to the right hand end of an arm 87 that is integral with the sleeve 83 of the frame 81.

It will be noted from Figures 4 and 6 that the weighing bucket 52 is provided midway on its opposite sides with the oppositely projecting extensions 88 (Figures 4 and 6) which extend to points adjacent to the plates 80 and which cover the associated outrider bearings for protection thereof. The plates 80 are connected'to the extensions 88 by pin and slot connections which permit limited relative movement of the plates and the weighing bucket 52. These connections are shown best, in Figures 3, 4, 5, and 6, and comprise the pins 89 (Figure 5) carried by the bucket extensions 88 which extend loosely into the vertical slots 90, formed in the plates 8.0, it being noted that the slots are enlarged at their upper ends (Figure 3). With the frame 81in its normal position, the weighing bucket 52 is supported by the upright pins 77 and 78 on the commodity outrider.64, and the pins 89 are spaced from the lower ends of the slots 90, as shown by the full lines in Figure 3. However, if the arm 87 of frame 81 is pulled downwardly by the link 86, the plates 88 will be lifted upwardly by the frame 81 and the lower ends of the slots 99 will engage'the pins 89. This will lift the weighing bucket 52 so that its supporting posts 75 and '76 will no longer rest on the respective pins 77 and 78 of the outrider 64. The weighing bucket 62 will thus now be free of support from the lever 60 and can be dumped without having any elfect on the lever; To center the bucket 52 relative to the lever 60-when it is lifted free of the lever, the plates 80 are provided with the adjustable set screws 91 which extend inwardly into cooperative relationship with the outer ends of the extensions 88. During the weighing operation, the weighing bucket 52 can move vertically without having the pins 89 thereon contact with either the Upper or the lower ends of the slots 90, since the slots are sufliciently long and properly located to. prevent this. when the lifting frame 81 is in its normal weighing position. Thus,

even though the lifting mechanism is not carried by the weighing lever 60, it does not interfere with vertical movement thereof.

The weighing bucket dumping mechanism is illustrated best in Figures 3, 6, 7, 9 and 10. It comprises the adjustable connecting rod units 95 which are disposed above the frame 81 at each side thereof. Each rod unit 95 is pivoted to its respective plate by a pivot 96 located above and to the right (Figure 3) of the frame pivot 82. The opposite, end of'one of the rod units 95, that is the one the rear side of the weighing unit 22, is pivoted to the upper end of one arm ofa bellcrank lever 97 (Figure 7) which is keyed on the rod 84 outside the frame lifting arm 87 (Figure 6). The opposite end of the. other rod unit (Figures 3 and.6) is connected to a simple crank arm 97a which is keyed to the other end of the rod 84. The bellcrank lever 97 is swung about the axis of the rod 8 by means of a vertically movable link 98 pivoted to the-other arm thereof. It will be apparent that upward movement of the link 98 will swing the bellcrank lever 97 and the crank arm 97a about the axis of rod 84 and will exert a push on both of the rod units 95. This will cause the plates 80 to tilt to the left (Figure 3), about their supporting pivots 82, dumping the weighing bucket 52; as shown by the dotted lines in Figure 3. It will also be noted that the outer side of the bucket 52 is angled inwardly to facilitate dumping. During dumping, the right hand pin 89 will move into the upper end of its mating slot 98 and the left hand pin 89 will move into the lower end of its mating slot 98. As will be apparent later, the controls of our machine are such that dumping of the weighing bucket 52 will take place only after the bucket has been lifted from the weighing lever 60. To insure that the weighing bucket 52 will be dumped only after it is lifted from the supporting pins 7'7 and 78, in order to prevent damage to the scale bearings and other parts, the rodunits 95 are constructed as shown in Figure 9. Each of these rod units 95 (Figure 9) comprises a compression spring 188 disposed within the sleeve 182 which is pivoted directly to the bellcrank 97 or the crank arm 97a.

Themain part 99 of the rod unit 95 extends loosely into the sleeve 182 and is provided with a shoulder 103 (Figure 9) which engages one end of the spring 188. This part of the rod is pivoted directly to the bucket 52 at the point 96. if the weighing bucket 52 is lifted from its supporting pins 77 and 78 and a push is exerted on the rod units 95 by upward movement of link 98, the springs 18%) will not be compressed but the weighing bucket 52 will be tilted for dumping. However, if the weighing bucket 52. has not been lifted from its supporting pins 77 and 78 and the link 98 is moved upwardly to push on the rod units 95, the springs 184) will merely be compressed and no damage to the weighing lever 68 and its bearings will result.

The checkweighing unit 23 is practically identical with the weighing unit 22. This is true of the even-balance lever arrangement as well as the mechanism for lifting and dumping the bucket 11d of this unit. The bucket 110, as shown in Figure 2, is disposed to the left of and below the bucket 52 of the weighing unit 22 and, as shown in Figure 1, is disposed in the same vertical plane at the front of the machine. Thus, when the weighing bucket 52 is tilted outwardly to the left, the pellets P Weighed therein are dumped into the bucket 118 of the checkweighing unit 23. The chute 52a is in. the form of an inwardly directed U-shape guard or baffle and is supported by the frame extension 25a over the normal position of the bucket to aid in guiding the pellets, dumped from the weighing bucket 52, into the checkweighing bucket 118. The checkweighing unit 23 may be provided with any suitable type of indicating mechanism and this may be of the same type as the mechanism associated with weighing unit 22, or may be of adiiferent type. This indicating mechanism is preferably disposed in the housing 112 (Figure 2) that is carried by theframe 25 in association with the checkweighing unit 23. This housing 112 has a window 113 in Which a shadow indicator preferably travels across a visible dial. The window 113 preferably faces towards the front of the machine so that it is easily visible to an operator. The indicating mechanism associated with the lever 111 of the checkweighing unit 23 may be connected to any suitable type of over-and-under indicating mechanism for indicating the position of the lever in the checkweighing operation. However, we prefer to use that type indicator known as the Shadograph as previously described.

In Figures 14 to 16, we have illustrated means associated with the weighing lever 60 for controlling vibration of the feeding chutes 28 and 40 of the feeding unit 21. This means is adapted to cause a fast feed, then a medium feed, and finally a slow or dribble feed. The fast feed is controlled by means of a microswitch 115 supported by the weighing unit base 25b adjacent the weighing lever 66. This switch 115 (Figure is supported below the counterweight end of the lever 63 and is so operated by this end of the lever that when the lever is in underweight position, the switch is closed and the circuit to the vibrating unit 35 for the chute 28 is completed, causing fast vibration of the chute 28. This fast-feed circuit will be described later. The switch 115 is directly actuated by an adjustable setscrew 116, the lower end of which engages, at the proper time, the pushbutton 115:: of the switch 115. The screw 116 is carried by a bracket 117 which is supported by the extension 60a of the lever 69 in such a position that the lower end of the screw will engage the button 115a of the switch 115. As soon as the commodity end of the lever 60 starts its downward movement towards balanced position and the counterweight end moves up, the screw 116 moves away from the switch button 115a allowing the switch to open and break the fastfeed circuit. The position of setscrew 116 in bracket 117 can be adjusted to increase or decrease the feed time of the fast-feed circuit. Thus, the fast feed occurs for the desired time at the beginning of the weighing operation.

The medium feed is also controlled by the position of the weighing lever 60 and by a circuit to the vibrating unit which vibrates the main chute 23. However, in this instance, a photoelectric cell unit 126 is used as part of the control means for the circuit. This unit 129 is supported at the counterweight end of the lever 69 by the base 251] through the medium of a vertically disposed plate 121 attached thereto and disposed transversely of lever extension 6311 and spaced from the extremity thereof.

This plate 121 carries a light source 122 midway of the front and rear edges thereof. On the plate 121 in front of the light source 122, is a photocell 125 enclosed within a glass dust cover 123. Behind the light source 122, on the plate 12L is another photocell 127 which is enclosed within a glass dust cover 126. The photocell E is adapted to control the medium feed by controlling the circuit to the vibrating unit for the main chute 28. The photocell 127 is adapted to control the slow or dribble feed by controlling the circuit to the vibrating unit 39 which vibrates the dribble feed chute 4i). These photocell feed control circuits will be described later. The extension 63a of the counterweight end of the weighing lever 6i carries a pair of bracket arms 128 and 129 at the front and rear sides thereof which are pivoted for vertical swinging movement about a transverse pivot 130 on the extension 60a. The arms 128 and 129 extend parallel with the extension 680 and carry the flag-supporting arms 131 and 132, respectively, which are rigidly connected therewith and which extend outwardly beyond the end of member 66a. These arms 131 and 132 move vertically within slots in the housing of the unit 12%. The arms 131 and 132 carry, respectively, the light-interrupting flags 133 and 134 which depend therefrom. The flag 133 will be movable within the extension 60a of the lever oil vertically between the light source 122 and the photocell 125. The flag 134 will be movable vertically between the light source 122 and the photocell 127. The flag 133 is of less depth than the flag 134 or, in

other words, the flag 134 will depend more from the end of the lever extension 60a than the flag 133. With this arrangement, both of the photocells 125 and 127 will be blanked when the lever 60 is in underweight position since the flags 133 and 134 will be in their lower positions, thereby completing the medium and dribble feed circuits to the vibrating unit 35 for the chute 23 and to the vibrating unit 39 for the chute 49. At this time, the switch is closed and the fast-feed circuit to the vibrating unit 35 for the chute 28 is completed, as the lever 63 starts to move towards balanced position, the switch 115 opens, breaking the fast-feed circuit to the vibrating unit 35. At this time, the flag 133 is still in position to blank the photocell and maintain the medium-feed circuit to the vibrating unit 35. Continued vertical movement of the counterweight end of the lever 60, moves the flag 133 to such a position that light from the source 122 reaches the cell 125 and at this time, the medium-feed circuit will be broken. However, the dribble or slow-feed circuit will still be maintained because t. e flag 134 will still blank the cell 127. Further upward movement of the lever 60 into balanced position, as shown in Figure 16, will move the flag 134 to such a position that light will reach the cell 127 which will break the slow-feed circuit to the vibrating unit 39. Thus, in the movement of the lever 69 from underweight position to balanced position, the feeding unit 21 is controlled so that first there is a fast feed by the chute 2, then a medium feed by the chute 23, and finally, a slow or dribble feed by the chute 43. Each of the bracket arms 128 and 129 is provided with an adjusting screw l23a connected to the arm and the extension 911 for pivoting each arm independently about the pivot to adjust the vertical position of each of the flags 133 and 134. To aid in starting the lever 6% towards balanced position from an underweight position, a flex 135 (Figure l5) is provided on the bracket 136 which is supported on the base 25b so that when the lever 6% moves into underweight position, an adjustable screw 137, carried by the lever extension 66a, will engage the flex 13.3. Adjustment of screw 137 will vary the returning force exerted by the In Figure 17, we have illustrated means in association with the checkweighing lever 111 for controlling the classification circuits which will classify the weighed charge as it is checkweighed as being within tolerance, underweight, or overweight. This means is practically identical with the photocell and flag arrangement at the end of the weighing lever 60 and is associated with an extension of the counterweight end of the lever 111. It includes the flag-carrying arms 149 and 141 (Figure 17) which carry the light-interrupting flags M5 and 146 which are associated with the photocell unit 1 32.. The unit 142 includes the light source 148, the classification photocell 153, and the classification photocell 154, both of these cells being affected by the light source 143. The flag moves vertically between the light source 143 and the photocell 153 and the flag 14-6 moves vertically between the light source and the cell 154. The flag 145 depends more than the flag 146. These fiags are vertically adjustable in the same manner as the flags 133 and 134. With the lever 111 in underweight position, the flags 145 and 146 will be in their lowermost positions and both the cells 153 and 154 will be blanked. As will later appear, this will control the classification circuits so that the charge in the checkweighing bucket 11% will be classified underweight. If the lever 11]. moves into balanced position, the flags 145 and 146 will be in the positions shown in Figure 17 ant. t e cell 154 will be illuminated while the cell 153 will still be blanked. This will cause the classification circuits to classify the charge correct weight. If the lever 111 moves into overweight position, the flag 145 will be at such a height that photocell 153 will be illuminated along with photocell 154.

This will cause the classification, circuitsto classify the charge overweight.

In Figure 18, we have illustrated schematically the air system. for controlling lifting and dumping of the weighing bucket 52 and the checkweighing bucket 110. As shown in this figure, a cylinder and piston or ram unit 160 is used for controlling vertical movement of the link 86, which, in turn, controls verticalmovement of the lifting frame 81 for the weighing bucket-52. Similarly, a cylinder and piston or ram unit 161 is provided for controlling vertical movement of the link 98 which, in turn, controls the connecting rods 96 that control tiltingof'the Weighing bucket 52. For controlling liftingof the check-weighingbucket 110, there is provided the cylinder and piston or ram unit 162, and for controlling dumping of the bucket 110,.there is provideda cylinder and piston or ram unit 163.

The air supply to the cylinder 160 is controlled by a pilot-operated four-way valve 164 which is connected to the cylinder of unit 160 by means ofthe upper line 165, and the lower line 166. The cylinder and piston unit 161 is controlled by the pilot-operated four-way valve 167 which is connected thereto by means of the upper line 168 and the lower line 169. The pistons 162 and 163 of the checkweighing unit are controlled in the same manner by pilot valves 170 and 171,.the valve 170 being connected to the unit 162 by the upper line 172 and the lower line 173 and the valve 171 being connected to the unit 163 by the upper line 174 and lower line 175. The fourway valves 164, 167, 170 and 171 are controlled by the solenoid-actuated pilot valves 176, 177, 178 and 179, respectively, which are actuated at the proper instants by the electric circuit to be described later. The solenoid valves 176, 177, 178-and 179 are connected by the respective lines 180, 181, 182, and 183 to the main air supplyline 184 which is connected to a suitablesource of filtered and regulated air and is under the control, of a main valve 165 which is manually, operable. The fourway valves164, 167, 170-and 171 are connectedby the respective lines 186, 187, 188 and 189 to the main supply line 184. The valve 164 is provided with a pair of throttle valve fittings 190 and 191, the valve 167 is provided with a pair ofthrottle valve fittings 192 and 193, the valve 170 is provided with a pair of throttle valve fittings 194 and 195, and the valve 171 is provided witha, pair of throttle valve fittings 196 and 197. Each of these fittings is provided with a needle valve which, in the usual manner, is, under the control of a screw 198 (Figure 18) to variably adjust the size of the exhaust opening thereof.

The particular structure of 'eachfour-way valve and each solenoid pilot-valve, is shown by the example given in Figure 19. Thisfigure showsthe four-way valve, the associated pilot valve 176, and the ram unit 160 which they control. The four-way valve 164 is of the spool type and comprises the vertically movable spool 200 which is slidably mounted in thehousing 201, and which has the annular passageways 2011) and 2010 formed therein. The spool 200 is normally-kept in its lowermost P081: tion by means of a compression spring202 disposed between its upper end and the upper end, of the housing 201. In this lower position,,indicated by dotted linesin Figure 19, which is its normalpositiomthe pistonrof unit 160 will be in its upper position as indicated bydotted lines. At this time the spool 200 willexpose the line 165 and will connect it, to the vent line connected to the throttle valve 190 so that air can-exhaust from the upper end of the cylinder. Also at this time the air supply, line 186 is connected to the line 166 through the passageway 2010, thereby supplying pressure to the lower end of the cylinder of unit 160 to maintain the piston thereof in its upper position and the weighing bucket lifting frame 81 in its lower position so that, at this time, the bucket 52 is supported on the lever 60. The solenoid-actuated pilot valve 176 is normally closed, so that valve 164 is in--the position described above, butwhen energized will be opened. It comprises a valve piston 203 which is nor mally held in its lower position by means of a spring that when the solenoid coil 206 is energized, the vent 208.

is closed, air is supplied to the valve 164 from the line 180, through the valve 176 and through the line 207, so as to lift the spool 200 of the valve 164 against the force of the spring 202. This, as shown in full lines in Figure 19, will connect the air supply line 186 to the line 165 through the passageway 201b, and supply pressure to the upper side of the cylinder of unit 160 thereby moving its piston downwardly and lifting the frame 81 and the bucket 52 from the weighing lever 60, and will allow the air to exhaust from the lower end of the cylinder of the unit 160, through the line 166, which will now be connected to the line of the throttle valve 191 through the passageway 2010. As soon as the solenoid 206 is deenergized, the spring 204 of the valve 176 will move the piston 203 to its lowermost position, disconnecting the line 180 from the line 207, connecting the line 207 to the vent 208 of the valve 176, and thereby permitting the spool 200 of valve 164 to return to its original position.

The other pilot valves 177, 178, and 179 are identical with that described and are connected to the respectively associated four-Way valves 169, 170 and 171 by the air lines 209, 210 and 211, respectively. Normally, the pistons of the units 160 and 162 are in their uppermost positions while those of the units 161 and 163 are in their lowermost positions, as shown in Figure 18. The fourway valve 170 for controlling the ram unit 162 is identical with the valve 164. The other two valves 167 and 171 are identical except. that the passageways therein are arranged, to supply air pressure to the lower sides. of the respective ram units 161 and 163 when the associated pilot valves 177 and 179 are energized.

Thus, it is apparent that when solenoid valve 176 is energized, the bucket 52 is lifted. The speed at which the bucket is raised can be varied by adjusting the screw 198 of throttle valve 191. The speed at which the bucket is lowered onto the lever 60 can be varied by a similar adjustment of the throttle valve 190. Each time the solenoid valve 177 is energized, the bucket 52 will be tilted into dumping position. The speed at which it is tilted can be varied by adjustment of throttle valve 193. The speed at which it is returned can be varied by adjustment of throttle valve 192. The checkweighing bucket will be lifted by operation of the solenoid valve 178, the speed of lifting of this bucket being controlled by adjustment of the throttle valve and the return movement being controlled by adjustment of the throttle valve 194. Tilting of the checkweighing bucket 110 occurs when the solenoid valve 179 is-energized, the speed of tilting being controlled by adjustment of the throttle valve 197 and itsv return movement being controlled by adjustment of the throttle valve 196.

The electric circuit for controlling the various units of our machine is illustrated in Figures 20 and 20a. With reference to Figure 20, the main input lines 211 and 212 lead from a suitable source of power, preferably 110 volt, 60 cycle. These lines are controlled by the line switch 213. The lines 211 and 212 are provided with the usual fuses, 214 and 215. The dial light 216 for the indicating mechanism of the weighing unit 22, and the dial light 217, for the indicating mechanism of the checkweighing unit 23, are provided and current of proper voltage is supplied thereto by means of the respective power transformers 218 and 219 the primaries of which are connected in parallel with the lines 211 and 212' by the lines 220 and 222, and 220 and 221, respectively. Also, connected in parallel with the lines 211 11 and 212 by means of the line 222 is the primary of an isolation transformer 223, and associated with this transformer 223 is a voltage-regulating transformer 224. This transformer 224 is of such a type that it supplies 115 volt alternating current isolated and regulated voltage to all the amplifiers for the photocells 125, 127, 153 and 154. Any variations in the line voltage will not atfect operation of these photocell amplifiers. The line 225 leading from the secondary side of the transformer 224 is connected to a line 226 which, in turn, is connected to the primary of a power transformer 227. The first of the secondaries of this transformer 227 is connected by a line 228 to the heaters of the thyratron tubes 229 and 233 which amplify the current from the photocells 127 and 129 and control the lifting and tilting circuits for the weighing bucket 52. The next of the secondaries of the transformer 227 is connected by a supply line 230 to one side of the light source 122 which is grounded at its other side. This light source, as previously indicated, is associated with the counterweight end of the weighing lever 60 and controls the photocell 125 which, in turn, controls hte medium feed of unit 21 and controls the photocell 127 which, in turn, controls the dribble feed of such unit. The cathodes of photocells 125 and 127 are connected to a line 231. The line 231 is connected to ground through the line 230. The anode of the cell 125 is connected by a line 232 to one of the grids of the thyratron tube 233. The anode of the cell 127 is connected by a line 234 to one of the grids of the thyratron tube 229. The other grid of this tube 229 is 9 connected to the line 235, which also connects to the cathode of this tube and to a line 236 which is connected to all of the secondaries of the transformer 227 which is connected to ground. The line 236 has the resistances 237, 238 and 239 therein and is connected to one of the movable contact arms 248 of a relay 241 which is controlled by the thyratron tube 229. The resistance 238 in the line 236 cooperates with an adjustable contact 242 which is connected to a resistance 243 and to the line 234, and also to the first-mentioned grid of the thyratron 229. The potentiometer formed by the contact 242 and the resistance 238 provides voltage adjustment means for varying the grid bias on the tube 229. The plate of tube 229 is connected by a line 244-, which has the resistance 245 therein, to the coil of the relay 241 and to a condenser 246 associated therewith, these components being also connected to the line 236 which connects with a fixed contact point 248, associated with the movable contact 248 of the relay 241. The line 236 also connects with the coil of the relay 249 which is controlled by the thyratron 233, and with the condenser 250 associated therewith, these components being connected by the line 251, which has a resistance 252 therein, to the plate of the tube 233. Connected to the line 232 and to the first-mentioned grid of tube 233 is a resistance 253 and the movable contact 254 of a potentiometer which controls the grid bias on the tube 233. This potentiometer includes the resistance 255, with which the movable contact 254 cooperates, and which is in line 256 along with the associated resistances 257 and 258. The line 256 shunts the line 236, which is connected to one side of all of the secondaries of the transformer 227, as previously indicated, and the line 259, which is connected to the other side of the last secondary of this transformer and is also connected to the line 236 as indicated. The other grid of this thyratron 233 is connected to the line 2.60 which also connects to the cathode of this tube and to the line 256.

As indicated previously, the thyratron 229 controls the relay 243i and the thyratron 233 controls the relay 249. These relays control the feeding unit 21, the relay 249 controlling the medium feed and the relay 241 controlling the slow feed thereof. The thyratron 233 controls the medium feed relay 249 and, in turn, is controlled by the medium feed photocell 125. The thyratron 229 12 controls the slow feed relay 241, and, in turn, is controlled by the slow feed photocell 127. The relay 241 includes the movablecontact arm and associated contact point 248, previously mentioned, and the movable contact arm 261 and the associated contact point 262. The arms 240 and 261 are ganged together and with the coil of the relay 241 normally deenergized, the arms 240 and 261 are spaced from the respective contact points 248 and 262. The relay 249 includes the movable arms 263 and 264, the arms 263 serving no purpose, but the arm 264 being associated with the contact point 265 from which it is spaced with the relay coil normally deenergized. The line 236 which leads from the contact point 248, is also connected to a line 266. This line 266 has the microswitch 115 connected in series therein, this switch being actuated by the weighing lever 60 of the unit 22 for fast-feed control of the feeding unit 21, as previously indicated. The line 266 is connected to one side of the coil of a fast-feed relay 267, which is grounded at its other side, and is also connected in parallel with a fastfeed indicating light 268. The contact point 262 of the relay 241 is connected by the line 269 to the coil of a slow-feed relay 270 and is also connected in parallel with a slow-feed indicating light 271 by a line 272. The line 269 connects to the line 221 which connects to the main line 212, and the line 272 connects to the power line 211. The arm 261 of the relay 241 is connected to the line 269 which connects to the line 276 that is connected to the arm 264 of the relay 249 and to a line 277 that connects to the power line 211. The contact point 265 of the relay 249 is connected in the line 276 which has the coil of a medium-feed relay 179 connected therein and is connected to the line 221 and which is also connected to a line 280 that has a medium-feed indicating light 278 connected therein, the line 280 also connecting to the line 272.

A line 281 leads from the power line 211 and connects with a line 282 which has a main feeder switch 283 connected therein, in series. The line 282 connects to a rectifier 284 through a line 285 and to a rectifier 286 directly. The rectifier 284 supplies direct current to a rheostat 287 Which includes a resistance 287a, connected in the line 285, and a movable contact 288 connected to a line 289 that connects with the contact point 290 of the relay 267 and with the line 285. The rheostat 287 is by-passed by the line 289 when the relay 267 is energized, thus connecting the fixed contact point 290 to the movable arm 295 of the relay 267. The line 285 is provided with another resistance 291, which is associated with the medium-feed test switch 292, connected therein, the line 285 also connecting to the contact point 293 of the relay 267. The relay 267 is provided with the ganged arms 294 and 295, the arm 294 serving no function and the arm 295 moving between the points 290 and 293, and being in contact with point 293 with the coil of the relay 267 normally deenergized. The rectifier 286 supplies direct current to a rheostat 296 which includes a resistance 296a, connected in the line 282, and a movable contact 297 associated with the resistance and connected to the line 282. The line 282 also has connected therein the slow-feed test switch 298 and is connected to the movable contact arm 299 of the relay 279. The relay 279 also includes the movable contact arm 300, the arms 299 and 300 being ganged together and being associated with the respective contact points 301 and 302, the arm 299 engaging the point 301 and the arm 30!? being spaced from the point 302 with the coil of the relay 279 normally deenergized. The contact point 301 is connected by the line 282 to the movable contact arm 304 of the relay 270. The contact point 302 is connected in the line 285 which has the coil of the main chute vibrating unit 35 connected therein, the line 285 also connecting to the main line 212 through the lines 306 and 307. The line 285 also connects to the line 282 and this line 282 has connected therein the coil of the dribble feed chute vibratai'raaoer ing unit 39, this line also including, thecontact point309.

mally deenergized, the arm 311 is spacedfrom the. point; 311a, the arm 310 is spaced from the point 313, and,

the arm 304 is spaced from the point 309. The point 313 is connected to a line, 314, which leadsto a selector. switch deck 315. The point 311a is connected in the line 312' which leads to one side of the coil of arelay 317, the other side of the coil being connected to ground. The purpose of the switch deck 315, and of, the relay 317 will be discussed later.

The line 266, which includes th'emicroswitch 115, has a fill-test switch 318 connected therein. 'The line 266 crosses the line 236 and is connected thereto at that point.

and its end is also connected to the line 236. Connected in the line 236 parallelwiththe switch 318 is the filler control deck 319 of the selector switch. This switch deck includes the movable contact selector arm 320which is adapted to selectively engage the contact'points' 321, 322 and 323, for. semi-automatic, automatic, or manual operation of the feeding unit 21. Connected to the point 323 and to the line 236 in parallelwith switch 318 is the manual-fill push-button switch 319a for manually controlling filling of the bucket 52' of the weighing unit 22. The points 321 and 322 are separately. connected to the line 236. Also connected in the line 236 isthe movable contact arm 324 and the associatedcontact point 325 of the time-delay relay 326, the arm 324 engaging the point 325 with the coil of the relay 326'normally deenergizedl The line 236 also connects to the line 259'leading from the transformer 227. The coil of, the relay 326is connected in the line 327 which connectsat one end with the power line 221.

As will be explained more in detaiLlater, the microswitch 115 controls the fast-feed relay.267, which, in turn, controls the supply of unregulated and Iunfiltered. direct current from the rectifier'284 to the vibrating unit 35'.

The medium-feed relay 279 is controlled by the relay 249 and controls the supply of regulated direct current from the rectifier 284, through the rheostat 287, to the vibrating unit 3,5. Rheostat 287 can be adjusted'to .vary the intensity of vibration ofthe unit 35"for the. medium feed. The slow-feed relay 270 is controlled bygthe relay 241 and controlsthe supply. of regulated direct current from the rectifier 286' through the rheostat 296, to the vibrating unit 39. The rheostat 296' can be adjusted to vary the intensity of vibration of the unitj39 for the slowv feed. The normally-closed main feed'switch 283'is manually operated and is in the common .line of the circuits for all three feeds, fast, medium andslow, and'is used'for testing and for emergency stop. The switch 292 is manually operated for medium-feed testing, and the, switch 298 is manually operated for slow-feed testing. Theselector switch deck 319can be. set for automatic, semi-automatic or manual operation of the feeding unit21, and-when set for manual operation, the pushbutton switch 324"can be manually operated. The tim'egdelay'relay 326j controls the circuit to the selector switchdeck 319 and thereby to the fast-feed microswitch 115; and; in conjunction with the respective thyratrongtubes'233 and 229, to the mediumfeed relay 249 and, the. slow-feed relay 241.

Another time-delay relay 328 isiprovid'edso that when the circuit is first'energizedb'y means off the. main line switch 213, the voltage, is prevented from being applied to the circuits for controlling lifting and tilting of: the Weighing bucket 52,- untilthe thyratron tubes, 233, and 229 have reached a stableoperating temperature. This relay 328 includes a movablecontact arm .329; co,n nected' in the line 236 in association with a contact'point 330,

the. arm being spaced from thev Point with the. coilfofjthe,

relay 328 normally deenergized. Thecoil offtherelay 32.8. is. connected in the. line 277, which-isconnected directly.t0 the mainline, 211. and to the main line 212 through the, line 331. The relay- 328 also includes. the

movable contact arm 332 which is ganged with the arm 329' thereof. Thearm 332 and an associated contact point333are connected in a line 334 which is connected to ground, the arm 332 being spaced fromthe contact point 333 with the coilof the relay 328' deenergized. Also, connected in the line 334.is a-condenser 335, and on opposite sides of this condenser a line 336 is con:

nected'to the line 334. This line 3.36 has connected inv it the secondary ofan isolation transformer 337, a resistance 338, a, condenser 339,,anda rectifier 340. Across: the line 336 is connected another rectifier 341. The, pri-; mary. of 'the transformerv 337 is connected in a 1ine.342. which is. connected to the power lines 211 and. 212.

through the respective, lines 343. and 331; Theltranse former 337 supplies isolated l10 volt alternating current. andthe rectifiers 3.40 and 341. are arrangedin sucha.

manner that the input voltage is rectified and then-doubled. The line 334 also connects with the movable. con-- tactarrn 344 of.a-relay= 345. The. coil of thisrelay hasone side. grounded and is. energized and deenergizedthrough the line 346, by means, to be described later, and when deenergized, the arm.3.44.is spaced from the asso.-, ciated contact point347. This point is connectedin the line 334Jto which the coil of a relay. 349 is connected,,its other side being grounded. Therelay 349 includes the gangedimovable contact arms 350 and 351. The arm 350 is connected to one, side of atcondenser 352,.the:

other side being grounded. The arm 350-moves betweenthe' two contact points 353 and 354, ,beingin contact with.

thepoint 354Iwiththe coil of the relay, 349' normally deenergized.. The arm351 is-connected in the power line. 327and is normally spaced. from a contactpoint355, with which his associated, ,with the coil of,the relay-.3,49. normally deenergized. Thepoint'355 is connected inthe. line 327 which is connected to the. coil of. the time-delay relay 326. The contactpoint 354 is connected to a movable contactarm 356 of a rheostat. 357 which-alsoincludesthe resistance 3581 The resistance, 358 is. con. nected'to one side of a coil of arelay359, the other side. ofthe. coil being grounded. Thisrelay 359 includes the, movable contact arm 360 which is connected to. a:line 361 that is connected to. the contact point 353 of the relay. 349 and has a resistance 362 therein. The line 361 is connected to the line 334. The relay 359 includesa contact point 363 from which the associated arn1360 isspaced with the c oi1 of the relay 359 normally deenergized; The contact point 363 is connected to one side, of the. coil of a. relay. 364, the other side of the coil being connected to ground. This relay 364 includes the ganged movable contact arms 365, 366,,and 367. The arm 365 moves between the contact points 368-and 369,- being in contactwith point 368 with the coil of the relay 364. normally deenergized. The arm 366 is associated with a contact point 370 and the arm 367 is associated with a contact point371, these arms being out of contact with their respective points with the relay 364 normally. deenergized. The arm 365 is connected to one side of a condenser 372, the other side of v the condenser being connected to ground. The arms 366 and 367 are connectedby the line 373 to the power line 327. The contact point 369 is connected to the line 334 by a line 374 which includes a resistance 375. The contact point 368' provided for controlling the dumping or tilting of the weighing bucket 52 of the unit 22.. The line 379 also. connects to the power line 306. Connected parallel with the solenoid of the valve 177 is a pushbutton switch 380 which is in a line 381 that connects with the line 379 and with a line 382 on opposite sides of the switch. The potentiometer 377 includes a resistance 383 which is connected to the one side of the coil of a relay 384, the other side of the coil being grounded. This relay 384 also includes the movable contact arm 385 which normally engages the associated contact point 386 with the coil of the relay deenergized. The point 386 is connected to the movable contact arm 387 of the potentiometer 388. The arm 385 of the relay 384 is connected to a condenser 389 which has its other side grounded. Another contact point 390 is associated with the arm 385, the arm being disposed for movement between this point and the point 386. This point 390 is connected to the line 334 through the resistance 391. The potentiometer 388 also includes the resistance 392 which is connected to one side of a coil of the relay 393, the other side of this coil being grounded. This relay includes the movable contact arm 394 which moves between the contact points 395 and 396, being in contact with the point 396 with the coil of the relay 393 normally deenergized. The arm 394 is connected to a line 397. The contact point 395 is connected to a line 398 which leads to the coil of the relay 399, the other side of the coil being grounded. The contact point 396 is connected to the coil of a relay 400, the other side of the coil being grounded. The relay 400 includes the ganged contact arms 401 and 402, the arm 401 serving no function. The arm 402 is connected to the power line 343 and is associated with a contact point 404, from which it is spaced with the coil of the relay 400 normally deenergized. The point 404 is connected in the line 405, which is connected to the line 382, and in which the solenoid coil of the pilot valve 176 is connected, this line 405 also connecting to the line 379. As previously described, the valve 176 controls the lifting of the weigh scale bucket 52 preparatory to dumping it. The line 382 has the pushbutton switch 403 connected therein and which is adapted to be actuated manually to lift the weighing bucket 52.

The slow-feed relay 270 controls the application of voltage to the coil of the relay 317, which has one side grounded, through the line 312 previously mentioned. The relay 317 includes a contact point 406 which is connected to the line 312 and which is associated with a movable arm 407 of the relay. This arm 407 is ganged with another movable contact arm 408 of the relay which is associated with a contact point 409. With the coil of relay 317 normally deenergized, the arms 407 and 408 are spaced from the respective contact points 406 and 409. The arm 407 is connected to the line 398 which includes a movable contact arm 411 of the relay 399. Connected to the line 398 is a line 413 in which a pushbutton switch 414 is provided for manual dumping of the weighing bucket 52. This line 413 connects to the line 312 running from the relay 270 to the line 334. The relay arm 408 is connected to the line 413 by a line 415. The contact point 409 of the relay 317 is connected in the line 415 which is connected to a contact point 417 of the relay 399 and to a contact point 418 of the weighing-bucket dumping deck 315 of the selector switch. The coil of the relay 399, which has one side grounded, is connected at its other side to the line 398 as previously mentioned. This relay also includes the contact point 419 and the contact arm 420. The arms 411 and 420 are ganged together, the arm 411 being associated with the contact point 419 and the arm 420 being associated with the contact point 417 but being normally spaced therefrom with the coil of the relay 399 deenergized. The arm 420 is connected to a line 421, which is connected to the line 413, and the point 419 is connected to the line 398. The dumping-deck 315 of the selector switch includes the manual-setting contact point 418, previously mentioned, the automatic-setting contact point 422, and the semi-automatic setting contact point .423. Cooperating with these points is the movable contact or selector arm 424. The points 422 and 423 are.

separately connected to the line 314 which leads to the contact point 313 of the slow-feed relay 270. The arm 424 is connected to one side of the coil of the relay 425, the other side of the coil being connected to ground. This relay includes the ganged movable contact arms 426 and 427 which are in contact with the respective points 428 and 429 with the coil of the relay 425 normally deenergized. The arm 426 moves between the contact point 428 and another contact point 430 from which it is normally spaced. The arm 426 is connected to one side of a grounded condenser 431 while the arm 427 is connected to the line 312 which leads from the slow-feed relay 270 to the line 334. The contact point 430 is also connected to the line 312 by a line 432 which includes a resistance 433. The point 428 is connected to the line 346 and the point 429 is connected to the line 397.

As will be explained more in detail later, the slow-feed relay 270 controls energization of the relay 425 when the selector switch deck 315 is set for automatic or semi-automatic operation. Also, the relay 270 controls energization of the relay 317 and this relay is locked in the circuit at the proper time through the relay 399. The relay 399 is energized and locked in the circuit at the proper time through the relays 393. The relay 425 controls energization of the relay 345, in a manner which will be explained later, through the line 346. The relay 400 is controlled by the relay 425 to operate the raise-valve 176, through the line 435, connected to relay 425, and eventually through the relay 393 in a manner to be described later. The relay 393, when energized, will prevent operation of the valve 17 6 by the relay 400 and the time during which the valve is held inoperative can be adjusted by potentiorneter 388. The switch 403 can be used at any time to manually control the valve 176. The relay 345 also controls energization of the relay 349. This relay 349 controls energization of the relay 359, which, in turn, controls energization of the relay 364. This relay 364 controls the dump-valve 177 for the weighing bucket 52. The time during which the weighing bucket 52 is tilted outwardly can be adjusted by means of the potentiometer 357. The switch 414 can be actuated to manually dump the weighing bucket 52 when the selector switch deck 315 is set at manual position. The switch 380 can be actuated at any time that switch 403 is closed to dump the weighing bucket 52. The relay 364 also controls energization of the relay 384 and this relay, in turn, controls energization of the relay 393. The time during which the bucket 52 is raised can be varied by adjustment of the potentiometer 377.

In the description of the electric circuit to this point, we have referred mainly to the various circuits for operating the feeding unit 21 and the weighing unit 22. Wewill now describe the circuits which control the checkweighing unit 23. These circuits include circuits for controlling the classification of the powder charge being checkweighed as correct weight, underweight and overweight, and circuits for controlling the raising and dumping of the checkweighing bucket when the charge is correct weight and when it is out of tolerance.

The light source 148 associated with the checkweighing lever 111 receives its power from a power transformer 440, it being connected in a line 441 which is connected to one side of a secondary winding of the transformer and to the line 231 which is connected to the cathodes of the filler controlling photocells and 127. One side of the primary winding of this transformer 440 is grounded and the other side is connected to the line 225 which leads from the secondary of the transformer 224. The cathodes of the photocells 153 and 154, which control the weight classification circuits of the checkweighing unit, are connected in parallel to the line 231, which is grounded. The anode of the photocell 153 is connected by a line 442 to a grid of a thyratron tube 443, and the anode of the photocell 154 is connected ground lead from oneside of each 17 by a line 444toa grid of a'thyratron tube 445. As will later appear, the tuhe4i3 plifies'curr'entfrom the photocell' l53 and controls lc .cuits for classification of the charge being checkwe'ighed' rnsm correct to overweight, and the tube 445 amplifies current from the photocell 154 and controls circuits'for classificationof the charge from under to correct weig t. Theline' 441 is a common 7 c c of the three secondary windings of the transformer 440 andthis provides ground for the resistances 4416, 447 and 448 connected therein. The line 441 has connected therein a movable contact arm 449 of a relay 4 50 [which is controlled by the tube 443. The resistance 447 has a movable contact arm 451a in contact therewith and this aim is connected to a resistance 452a which is connected to the first-mentioned grid of the tube 443. Thus,'there is provided a potentiometer which controlsthe grid bias on the tube 443. The other grid of the tube 443 is connected to a line 451 whichconnects to the line 441. The cathode ofthc tube 443 is also connected to this line 451. The heater of this tube is grounded and is connected to one side of the secondary winding of the transformer 440 by a ,line 452.

I The plate of this tube is connected by a line 453 to the coil of the relay 450, this line including a resistance 454. Connected to the line 441 is a line 455 which includesthe resistances 455a, 456 and 457, the line 441 also connecting to a line 458. The line 458 connects at one end to the line 441, and includes a contact point 459 of a relay 460. Associated with the resistance 456 is a movable contact arm 461 which connects, with the resistance 462 that is connected to the first-mentioned grid of the tube 445. Thus, there is provided a potentiometer for controlling the grid bias on the tube .445. The other grid of the tube 445 is connected by a line 463 to the line 45 5. The cathode of this tube is also connected to the line 463. The heater of this tube 445 has one side grounded and the other side is connected to the line 452. The

plate ofthis tube is connected by a line 464, having a resistance 465 therein, to thecoil of a relay 466 which is controlled by the tube 445.

Connected parallel withthe coil of the relay 458 is a condenser 467 and these members are connected to the line 441 which includes a contact point 469 of the relay 450. ,The line441 is connected to the contact point 470 of a time-delay relay471. The coil of. this relay receives voltage. by means of the lines 211 and 331 and the relay includes the movable contact arm 472 which is associated with the point 470 but is spaced. therefrom with thecoil of therelay normally deenergized. The arm 472 is con nected in. the line 441 which .connects to the power line 458. .A condenser 473 is connected parallel with the coil of ,therelay 466, and these members are also connected to the line1441. underweight classification light 474 is connected ina 1ine 475 which runs from the line .464.to the line441. An; overweight classification light 476 is connected in a line 477 which is connected to the line 475 and to the'line' 453. The relay 468 is also a time-delay relay and includes the ganged arms 478 and .479. The arm 478 is connected to one side of a con denser 480, the other si'de being grounded. The arm 479 is connected in the line'458, along with the contact point 459 with which it is associated. The arm 478 moves .between a contact point 481, which is connected to the line 421 in which the coil of a relay 482 is connected, and a contact point468 which isconnected to one side of a resistance,.the other sidelbeing grounded. With the coil of the relay 460fnor'mally deenergized, the arm 478 is in .Contact with the, point 481 and the arm 479 is in contact with the point 459.

As will be explained more in detail later, the time-delay relay471 prevents voltageffrom being applied to the classification circuits until the thy'ratron tubes 443 and 445 have reached a stable operating temperature. Also,

the time-delay relay 460 provides a sufficient interval,

after return of the checkweighing bucketl10 to'its original horizontal position, to permit balance of the checkwei'ghing lever '1 11"befo're the classification is made on the checkweighing unit23. The tubes 443 and 445, as previously indicated, "control the classification relays 450 and 466, respectively. v 1

The overweight classification relay 450 includes the arm 449, previously mentioned, and the arm 483 ganged therewith. The arm 449 is associated with the contact point 469, previously mentioned, and the arm 483 is associated with a contact point 484. With' the coil of the relay 45h normally deenergized, the arm 449 is spaced from the point 469 and the arm 483 is in contact with the point 484. The point 484 is connected in a power supply line 485 in which the two coils of a double-coil relay 486 are connected. The relay 486 includes the ganged movablecontact arms 487, 488, 489, 490, 491, 492, and 493, the arm 489 serving no purpose. The 'arm 487 cooperates with a contact point 494 and the grounded arm 488 cooperates with a contact point 495. The arm 496 moves between the contact points 496 and 497, the arm 491 moves between the contact points 498 and 499, the arm 492 moves between the contact; points 500 and 501, and the arm 493 is associated with the contact point 502. With the coils of the relay 486 normally deenergized, the arm 487 is spaced from the point 494, the arm 488 is spaced from the point 495, the arm 498 is in contact with the point 497, the arm 491 is in contact with the point 499, the arm 49 2 is in contact with the point 501, and the arm 493 is spaced from the point 5 82. The underweight classification'relay'466 includes the ganged arms 503 and 504, the arm 503 serving no purpose, the arm 504 contactingwith a contact point 505' when the coil of the relay 466 is normally deenergizeds The point 505 is connected to a line 506 in which the coils of a double-coil relay 507 arconnected, line 586 connecting to the power line 485. -The arm 504 is connected in the line 506 along with the point 505. With the coil of the relay 466 normally energized, the arm 584 contacts the point 505' The relay507 includes the gangedcontact arms 508, 509, 510, 511, 512, 513, and 514. The arm 508 cooperates with the point 515 and the grounded arm 509 cooperates with thepoint 516; The arm 511 moves between the contacts point 517' 'and 518, the arm 512 moves between the contact points 519 and 528, the arm 513 moves between'the contact points 521 and 522, and the arni 514 rnoves between the contact points 523 and 524. 'With the c'oilsof the relay 507 normally'deenergized, the arm 508is spaced from the point 515, the arm 509 is spaced from the point 516, the arm511 is in contact with the point 518, the arm 512 is in contact with the point 520, the arm 513is in contact'with the point 522,'and'the arm 514 is in "contact with the point 524. The point'494 oftherelay 486 is connected tofthe line 485, the point 495'is also connected to the line 485, the point 496 isconnectedto a line 525, the point 497 is connected to a line526, which also connects to 'the line 525, thepoint' 498 is connected to a line 527, the point 499 is connected to "a line 528 which"connectsto the line 527, the point 500 is connected toa line 529 which connects to the line 485, the point 581 is connected to a line 530, and the point 502 is connected to a line 531 which connectsto the line 485. 1 Th'e'arm 498 is connected in the line'526 which includes the point "517 of the relay 507. The line 525 connects with the line 526 and this latter'line'has connected therein the point 518 and the arm 511 of the relay 507. The line"527, connected to the point 498,has"the overweight classification light 533'con'nected therein and the line 528 has the correct weight classificationlight'534 connected therein in series with the points 499" and the arm 491, the line 528 also having connectedthereto, the point 519 of the relay 507. The line 527 connects to a line 535 in which an underweight classification light 536 is connectedhthis line 535 having the point 520 of the relay 587 connected therein. The line 485 has the arm 513 and thepoint 19 522 of the relay 507 connected therein. The line 531 connects with the line 485 and has the coil of a relay 537 connected therein. The arm 492 is connected in the line 530 with the point 521 of the relay 507. The arm 493 is connected in the line with the point 523 of the relay 507. The point 524 of the relay 507 is connected in the line 540 which connects to the line 531. The contact point 515, of the relay 507 is connected to the line 506, the point 516 to the line 506, the point 538 in the line 526, and the point 519 in the line 528.

The relay 482 is energized by the time-delay relay 463. This relay 482 controls energization of the relay 545 which controls energization of the relay 546 which setsup the classification relays 486 and 507 for operation.

The relay 482 includes the movable contact arm 547 which is connected to one side of the condenser 548, the other side being grounded. The arm 547 moves between the contact points 549 and 550, being in contact with the point 550 with the coil of the relay 482 normally deenergized. The point 549 is connected to one side of a resistance, the other side being grounded. The point 550 is connected to the coil of the relay 545 by the line 552 which connects with the line 485 through the coil of the relay 545. The relay 545 includes the movable contact arm 553 which is connected in the line 556 that connects to the line 485. The arm 553 is normally spaced from a contact point 555, with the coil of the relay 545 deenergized, the contact point being connected in the line 556 in which the coil of a relay 546 is connected and which is connected to ground. The relay 546 includes the ganged movable contact arms 557, 558, 559, 560, and 561, all of which are all connected to the ground line 556. Connected between the arms 559, 560, and 561 and the ground line 556 are the condensers 562, 563, and 564, respectively. The arm 557 moves between the contact points 565 and 566, the arm 558 between the contact points 567 and 568, the arm 559 between the contact points 569 and 570, the arm 560 between the contact points 571 and 572, and the arm 561 between the contact points 573 and 574, the arms 557, 558, 559, 560, and 561 contacting the respective points 566, 568, 570, 572, and 574 with the coil of the relay 546 normally deenergized. The point 565 is connected to the line 586 by a line 575, the point 566 to the arm 508 of the relay 507 by a line 576, the point 567 to the line 485 by a line 577, the point 568 to the arm 487 of the relay 486 by a line 578, the point 569 to the line 485 by a line including the resistance 580, the point 570 to a line 581, the point 571 to the line 485 by a line 579 including the resistance 582, the point 572 to the line 583, the point 573 to one side of a resistance, the other side being grounded, and the point 574 to a movable contact arm 585 of a potentiometer 586. The contact 585 cooperates with a resistance 585a which is connected to a line 587 that includes the coil of a relay 588, the line 587 being connected to the line 485. The relay 588 also includes the grounded movable contact arm 589 which is spaced from a contact point 590 with the coil of the relay deenergized. The point 590 is connected to the line 526 which leads to the arm 511 of the relay 507. This line 526 is connected by the line 540 to the arm 514 of the relay 507. As will be explained in detail later, relay 588 controls the dump valve circuits whether the classification s overweight, underweight, or correct weight, and the interval during which this relay is energized can be varied by means of the potentiometer 586.

Power is supplied to the classification relays and other units of the circuit by means of an isolation transformer 592, the primary of which is connected in a line 593. The power lines 281 and 307 are connected to the line 593 at opposite sides of the transformer primary. A l ne 594 is a common ground and one side of the isolatron transformer 592 secondary winding is grounded by the line 594. In series with the other side of the secondary winding of the isolation transformer 592, is a resistance 596, capacitor 597, rectifier 598, and capacitor 595 in the line 594. A rectifier 600 is connected between the capacitor 597 and the rectifier 598 to the ground line 594. This rectifier power supply, like the arrangement previously described,-receives the input voltage from the transformer 592, rectifies it, and then doubles it.

The time-delay relay 471 also includes the movable contact arm 601 ganged with the arm 472. This arm 601 is connected in series in the power line 222 with the solenoid 603 of an out'of-tolerance horn, and a contact point 604 associated with the arm 601, the arm and point being out of contact when the coil of the relay 471 is deenergized. Also connected in the line 222, in series, is a contact point 605 and a movable contact arm 606 of a time delay relay 607, the coil of which is connected in the line 221. With the coil of the relay 607 normally deenergized, the arm 606 is spaced from the point 605. Also connected in the line 221, in series, is a contact point 608 and a movable contact arm 609, of the relay 610, the line 221 connecting to the power line 593. The coil of the relay 610 is connected in a line 611 which is connected to the line 531 that connects to the line 485. With the coil of the relay 610 normally deenergized, the contact arm 609 is spaced from the point 608. The relay 537, the coil of which is connected in the line 531, includes the movable contact arm 610a which is connected to one side of a condenser 611a, the other side of the condenser being grounded. This arm 6160 is movable between the contact points 612 and 613, the point 612 being connected to the line 611 and the point 613 being connected to one side of a resistance, the other side being grounded. The arm 610a contacts with the point 613 with the coil of the relay 537 normally deenergized.

The relay 588 controls energization of the relay 537. The relay 537 controls energization of the relay 610 which, in turn, controls energization of the time-delay relay 607 that controls the circuit to the out-of-tolerancc horn 603 in conjunction with the arm 601 of the timedelay relay 471. The relay 607, like the relays 326, and 460, is constructed so that the time delay starts after the coil thereof has deenergized.

The line 583 leading from the contact point 572 of the relay 546 has connected therein the resistance 615 and associated movable contact 616 of a potentiometer 617.

The circuit so far described is shown in Figure 20. The remainder of the circuit which is now to be described is shown in Figure 20a.

As shown in Figure 2001, the circuit includes the selector switch decks 621, 622, 623, 624, and 625 which include the movable selector arms 626, 627, 628, 629, and 630, respectively. The arm 626 can selectively engage any of the contact points 631, 632, or 633; the arm 627 the points 634, 635, or 636; the arm 628 the points 637, 638, or 639; the arm 629 the points 640, 641, or 642; and the arm 630 the points 643, 644, and 645, for semi-automatic, automatic, or manual operation, the arms being shown set for automatic operation. The line 526 running from the classification relays 486 and 507 is connected in series to the points 632, and 635. The arm 627 is connected to the line 631 which leads from the point 497 of the relay 486. The point 633 is connected to the line 646 which connects to the line 526. The arm 626 is connected to a line 647 which connects to the arm 630. The point 631 is connected to a line 648 which connects to the line 526. The point 637 is connected to a line 649 which connects to the line 485. The point 639 is connected to a line 650 which also connects to the line 649 which is connected to the line 485. The arm 628 is connected to a line 651. The point 642 is connected to a line 652. The arm 629 is connected to the line 530. The point 644 is connected in the line 647 which includes the arm 630.

As previously indicated, the line 346 runs between the contact point 428 of the relay 425 and the coil of the relay 546 and'zto one v,side of the other side being grounded.

up relay 546. This relay 668 includes -tact arm-669 which is connected in the line 651,, and the. associated -contactlpoint670 which is connected to, one side of .the coil of a relay 671, the other side of -thecoil of arelay 680, "The points 677 and 678 in contact with; the

:relay'i345. .Gonnecteddn serieszin this line 34,6 are a movable;;contact i arm -652.--a-nd an associated contact point 653 of a.relay:654, .a-nd. a1-rnovable contactarm 655 and an associated.-contact;point 656of a relay 657. Also, as

previously indicated,-t-he line 397 runs between the con- 1 is also eonnectedt-inseries .to the-movable contact arm Y 662 and eontact'rpoint 663 of agbucket-raising deck 664 of the selector --switch,;and toone side of the coil of a relay 665,.the otherside :being grounded. The contact point-663 of the 'deck 664 is the automatic setting point and there is also :providedthe semi-automatic point 666, which-is connected to the line 583, and the manual setting point 667. The coil of the relay 665 is energized through the line 583 from the setting-up relay 546 only;

when arm 662 of deck.- 664 is onautornatic or semi-automane-position, and-its" period of,,energization can be varied-by the potentiometer 617. The line 581, as previously indicated, r,uns-fromthecontact. point 570 of-the The coil of this relay 668 is energized throughj'the line 581 from the settingthemovable conwhich is grounded, and to the contact point 672 thereof.

The coil of .this relay671 isenergized by the relay'668 whenfthe switch1decks623. is.set,on manual or semi-auto- :matic position. Thearmj 669 is spaced from the contact a point 670with thecoilof the relay energized. The relay -contact1arms 673 and 674 The'arms 673 is connected; in theline651 andthe arm 674=is connected "in the line' The line 485, which-runsfromtheclassification relays --486 and '507, connects in-series to the contact points 677 668 normally de- 671 also includes the movable which are ganged together.

rand .678,themovablecontact arm 679 and to one side of the other .sidebeing grounded. and the arm 679 are part of a relay- 681. This relay 681 has onesideof its .coilconnectedtin 'the'line652 and its other side grounded. This relay 681 also includes an armr682 which is ganged with the arm 679. The arm 679cooperates with the point 678 andlthe armvr682: cooperateswith' thepoint 677. The arm 682.is spaced' from the point 677 and the arm 679 is point.=678.with-the coil of the relay 681 normally deenergized. The arm 682 isconnected to the line .652. The relay:680;includes the ganged arms 683 and 684, the arm 683 serving no function and the arm 684 cooperating. with a contact point 685 from which it is spacedwith the coil of the relay 680 normally deenergized. The relayy681 is energized by: the classification relays 486, and. 507- only on. out-of-tolerance loads and only when theswitch' deck .624 is set for manual operation. Thisrelay'will control energization of the-relay 680. The point .685 of:;the;relay 680-is connected to a line686 and the arm'684 thereof is connected to a line 687. These lines- 686 and- 687 may be connected to suitable apparatus (not shown) for moving a receiver intoposition to receive..out-ofatolerance charges dumped from the checkweighing bucket 1-10.

The-.line 650 connects to. the contact arm 688 of a deck .689 of a: selecton-switch. which also-includes the .semirautomatic setting .point. ..690,-;the automatic; setting 546 and ineludesrthe potentiometer-617. This-line 583 thecoil-of the relay 668,;

point 691, and the manual setting p.oint .692. ,The point 690. is connected to a line693 which connects to one side of the coilof a relay 694, the other side of the coilbeing grounded. The coil of this relay 69.4 isenergizedv through switch deck 689, provided it is on semi-automatic position, and the deck 623 issirnilarly set. Th'e'relay 694 includes the ganged movable contact arms 695 and 696, the arm 695 serving no function and the arm 696 cooperating with a contact point 697 with which it" contacts the coil of the relay 694 normally deenergized. The point 697 and the arm 696 are connected inseries in the line 593 along with a point 699 and an associated movable contact arm 7.01 of the relay 665. The arm 701 is spaced from the point 699 with the coil ofthe relaynormally deenergized. The line 593 connectsto a line 700. The line 647, running from the switch deck 625, connects with a line 702, which connects with the line 593. This line 702 has the coil of a relay 703 connected therein. This relay is normally deenergized and includes a movable arm 704 which normally contacts a contact point .705 connected to one side of a resistance which has its other side grounded, the arm 704 being connected to one side of a condenser 707 which has its other side grounded. Thearm 705 is normally in contact with the contact. point 705 with the coil of therelay 703 deenergized. A contact point 708 of the relay 703.is connected toa line 709 in which the coil of a relay 710 is connected, the .line 709 connecting to the line- 702. The relay 710 includes the movable contact arm 711, which is connected to one side of the condenser 712 .which has its other side grounded. The arm 711 .moves between ,the contact points 713 and 714,. the arm being in contact with the latter with the coil of the relay 710 normally deenergized. The point 713 is connected to the resistance 715 whichis connectedtothe line 702. The,point'714 is connected to a line 716 in which-the coil of a relay 717 is connected, one side of this coil being grounded. This .relay 717 includes the movable contact arm .718, which, with the coil of therelay 717 normally deenergized, is spaced from a cooperating contact'point-719. The arm 71 8 andthe point 719 are connected in series in a line 720, in which the coil of a relay 721 is also connected, one side of this coil being grounded. The coils of the relays 703 and 710 are energized through the line 702. The relay 703 .includes the. ganged movable contactarms 722hand 723,

the arm 722 serving no purpose. Thearm 723 is connected in series in the line 220, with'a contact point'724 of the relay 721, the pushbutton switch 725 for dumping the checkweighing bucket 110, and the tpushbutton switch 726 for raising the bucket 110. The arm 723 is spaced from the point 724 with the relay 721 normally deenergized. Across the lines 220 and 306; there is connected the solenoid of the dumping valve179 for. the bucket of the chcekweighing unit 23. The solenoid of the raising valve 178 for the bucket 110 of. the checkweighing unit 23 is connected in the line 306 and this line 306is connected by a line 727 to one. of the contact points of the switch 726. The coil of the relay 654 is connected in a line 728 which runs from the line .306 to the line .593. The coil of the relay 657 is groundedlat one side and its other side is connected to a line 729 in whichthe contact point 730 and. the movable contact arm 731 of a time-delay relay 732 are connectedin series,,the line 729 connecting to the line 702. The line 702 is also connected to the movable contact arm 733 of a time-delay relay 734. The relayarm 731 is ganged with an arm 739 which serves no purpose and the arm 731 is spaced 7 32 normally deenergized. Thecoil of the relay 732 is s nn st dr at s 1i i 93a d l e a o. h twn c 23 therein a contact point 735 of the relay 671. The arm 674 of this relay is also connected in series in the line 593 which connects to the line 220. The coil of the timedelay relay 734 is connected in the line 709. This relay also includes the arm 736 which is ganged with the arm 733. The arm 733 is associated with the contact point 737 and the arm 736 is associated with the contact point 738, the arms being spaced from the points with the coil of the relay 734 normally deenergized. The arm 736 is connected in the line 306, which connects with the line 593, and the point 738 is also connected in this line 326. The point 737 is connected in the line 702 and the coil of the relay 741 is connected in this line, one side of this coil being grounded. This relay 741 includes the ganged movable contact arms 742, 743, and 744, the arms 742 and 743 serving no purpose. The arm 744 is grounded and is associated with a contact point 745 from which it is spaced with the coil of the relay 741 normally deenergized. The point 745 is connected to the line 792. The line 700, running between the switch deck 75% and the relay 734, has one section 746 of a pushbutton dumping-switch for the bucket 110 of the checkweighing unit 23, the other section 747 being connected in the line 651, which runs from the arm 673 to the line 702, the two pushbutton sections being ganged together, with the section 746 normally open and the section 747 normally closed. The line 700 connects also to an automatic setting contact point 751 and a semi-automatic point 749 of a deck 75% of the selector switch which also has a manual point 748. This switch deck also includes a movable selector arm 752 which is connected by a line 753 to the line 220. The coil of the relay 654 is energized through the line 728 and the line 366 under the control of the time-delay relay 734 as will be explained in detail later. The coil of the relay 657 is energized through the line 729 under the control of the time-delay relay 732. The relays 654 and 657 cooperate in controlling energization of the coil of the relay 345, which controls the action of the tilting valve 177 for the bucket 110 of the weighing unit 22, and lock-in with the relay 393, which operates the raising valve 176 of the weighing unit 22, as will be explained more in detail later. The coil of the relay 732 is energized under control of the relay 671. The coil of the relay 734 is energized through the switch deck 750, provided it is set for semi-automatic or automatic operation, and this relay controls energization of the coil of the relay 741, and activation of the raising valve 178. The relay 741 controls energization of the coil of the relay 703. The switch sections 746 and 747 serve as a manual switch for activating the dumping valve 179 of the checkweighing unit 23. The switch 725 also serves as manual means to activate the dumping valve 179. The switch 726 serves as a manual means for activating the raising valve 178. The switch composed of sections 746 and 747 can be actuated for manually controlling the dumping cycle of the checkweighing unit 23. The time-delay relays 697, 732, and 734 are also of the type that the time delay starts after the coil of the relay has deenergized.

Direct current is supplied for the classification circuits by means of the isolation transformer 754 which has its primary connected to the lines 220 and 728. The secondary of the transformer 754 is connected in a common ground line 755 which has connected in it, in series, a condenser 756, the transformer secondary, a resistance 757, a condenser 758, and a rectifier 759, the line 755 connecting to the line 702. Across the line 755 is connected a line 760 which has a rectifier 761 connected therein. Like the similar direct current power-supplying arrangements previously described, this arrangement receives the input voltage from the transformer 754, rectifies it, and then doubles it.

Although the selector switch decks 315, 319, 621, 622, 623, 624, 625, 664, 639, and 750 are shown at widely separated locations in the circuit, it is to be understood that these decks are all part of the same switch and that the selector arms of all decks are ganged together so that all are set simultaneously on corresponding automatic, semi-automatic, or manual selecting points.

Our weighing machine will now be described, in its operation, with all the selector switch decks 315, 319, 621, 622, 623, 624, 625, 664, 689, and 750 in automatic position. The main switch 213 will be closed and this will energize the dial lights 216 and 217. The manual weighing bucket-raising switch 403 will be open. The manual feeder switch 283 will be closed and the pushbutton feeder switch 319a will be open. The manual filling switch 324 will be open. The medium-feed switch 292 will be closed. The manually operable dumping switch 380 for the weighing bucket will be open. The slow-feed tcst switch 298 will be closed. The manual weighing bucket dumping switch 414 will be closed. The manually operable switch for controlling dumping of the checkweighing bucket will have its section 746 open and its section 747 closed. The manual switch 725 for controlling dumping of the bucket 110 will be open and the manual switch 726 for controlling raising of the checkweighing bucket will also be open. At the beginning of the cycle, the lever 60 of the weighing unit 22 and the lever 111 of the checking unit 23 will both be in underweight position, thus blanking the phototubes 125, 127, 153, and 154. The fast-feed microswitch 115, which is actuated by the lever 60, will be closed, thus energizing the relay 267 and the fast-feed indicating light 268.

With the lever system in the underweight position and the phototubes 125 and 127 blanked, the thyratron tubes 229 and 233 are conducting, thus energizing the mediumfeed relay 249 and the slow-feed relay 241. The relay 249 controls the relay 279 and the medium-feed indicating light 278 and the relay 241 controls the relay 270 and the slow-feed indicating light 271. Thus, the mediumfeed light 278 and the slow-feed light 271 are on and the fast-feed light 268 will be on because the fast-feed microswitch is closed, at the beginning of the feed cycle. The vibrating unit 35 is energized at this time, due to the fact that the fast-feed microswitch 115 is closed, so that material is being fed at a fast rate from the main chute 28. The rectifier 284 supplies 110 volt unregulated and unfiltered D. C. to the vibrating unit 35 through the contact arm 295 and the point 290 of the fast-feed relay 267, since the relay 267 has been energized by closing of the fast-feed microswitch 115, and through the contact arm 300 and the contact point 302 of the medium-feed relay 279, which has been energized by the tube 233.

As material is fed from the feeder into the weighing bucket 52, the lever 60 starts a continuous movement towards balanced position. At the instant the Weighing lever 60 leaves the underweight position, the fast-feed microswitch 115 is opened and thereby the fast-feed relay 267 and the fast-feed indicating light 268 are deenergized. When the fast-feed relay 267 is deenergized, the vibrating unit 35 serves to actuate the main chute 28 to deliver material at a medium rate of speed since now the rectifier 284 supplies the current to the vibrating unit through the medium-feed rheostat 287 and the fixed resistance 291, through closed switch 292, through the arm 295 and the point 293 of the fast-feed relay 267, which at this time is deenergized because of the opening of the fast-feed microswitch 115, and through the contact arm 300 and the point 302 of the medium-feed relay 279 which is still energized by the tube 233, the mediumfeed light 278 being on at this time. Upon further movement of the weighing lever 60 towards balanced position, the flag 134 carried thereby moves to such a position that light from the source 122 is permitted to reach the phototube 125. This causes the thyratron tube 233 to stop conducting and, therefore, causes deenergizing of the mediumfeed relay 249 which, in turn, deenergizes the medium-feed relay 279 and the medium- 

